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Einstein, UAlbany to Make Smallest Cancer Detector

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BRONX, N.Y., Nov. 20, 2006 -- A $2 million grant from the National Cancer Institute (NCI) will enable the study of tumor "microenvironments," where tumors interact with surrounding tissues, cells and chemicals in ways that all too often encourage cancer cells to invade other areas of the body in the process known as metastasis.

With the new NCI grant, John Condeelis, co-chair of anatomy and structural biology at Albert Einstein College of Medicine of Yeshiva University in Bronx, N.Y.,  and the principal investigator of the newly funded program, and colleagues will team up with researchers at the College of Nanoscale Science and Engineering (CNSE) at the University at Albany to develop a next-generation microchip that, when placed in a cancerous mass, can gather information on the presence of metastatic cells that would demand more aggressive cancer therapy.

"The NCI has placed a very high priority on understanding the 'dialogue' in tumor microenvironments that appears crucial for causing cancers to spread," said Condeelis. "This five-year Tumor Microenvironment Network grant will allow Einstein to influence the way research is carried out in this emerging and important field."

James Castracane, the project's co-investigator, who is head of the Nanobiosciences Constellation at CNSE, said, "By integrating cutting-edge science and engineering at the nanoscale level with vital biomedical research, it is our intent to provide deeper understanding of the causes of cancer metastasis and migration -- knowledge that is of critical importance in the treatment and, ultimately, prevention of cancer."

Condeelis has used the multiphoton confocal microscope to directly observe cellular interactions in the tumor microenvironment of live animal models of breast cancer. By placing an artificial blood vessel near tumors, he was able to collect motile cancer cells for study and to predict -- by the presence or absence of certain signaling molecules -- whether the tumor cells have the potential to metastasize.

The Einstein and Albany researchers will use nanotechnology, which involves studying and working with material on the molecular level, to design a "microchip" version of the artificial blood vessel that Condeelis has used successfully in animals. The microchip will be assembled from nanoscale components so that several different functions can be carried out within a very small package. The goal: to implant these tiny microchips -- just two to three cells in diameter and a tenth of a millimeter in length -- in human tumors, where they would remain for days or weeks. The chips would report remotely to scanners that would "read" them on the nature of the cells that infiltrate them--in particular, on whether metastatic cells are present that would call for more aggressive cancer therapy.

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In 2005, Einstein formed an alliance with UAlbany's CNSE to advance education and research in the rapidly growing fields of nanobiotechnology and nanomedicine. "This NCI grant marks a true milestone for this partnership, which combines the unique expertise and resources of both institutions to apply nanoscale principles to detect diseases and develop treatments for them," said Ira M. Millstein, chairman of the Einstein Board of Overseers. "We are committed to ensuring that the Einstein-Albany alliance will lead the nation in efforts to use nanotechnology to improve peoples' lives."

Einstein is one of nine research centers nationwide to receive a Tumor Microenvironment Network grant. In a departure from traditional NCI practice, the nine grant recipients are expected to collaborate closely during the five-year research period to improve technologies used in studying the tumor microenvironment. For example, principal investigators from all nine research centers will meet twice a year to exchange data and compare results that they obtain.

The other eight research programs receiving the NCI tumor microenvironment grants are located at the following institutions: Lawrence Berkeley Laboratory; Stanford University School of Medicine; Memorial Sloan-Kettering Cancer Center; Massachusetts Institute of Technology; Vanderbilt University Medical Center; University of Washington School of Medicine; Baylor College of Medicine; and Columbia University.

Published: November 2006
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The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
Albert Einstein College of MedicineBiophotonicschemicalsCNSECollege of Nanoscale Science and EngineeringindustrialMicroscopyNational Cancer InstituteNCINews & Featuresphotonicstumor microenvironmentsUniversity at AlbanyYeshiva University

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